Project description:RNA interference (RNAi) functions as an antiviral immune response in plants and invertebrates, whereas mammalian RNAi response has been found so far only in undifferentiated cells and in differentiated cells inactive in interferon (IFN) system or in infections with viruses disabling viral suppressors of RNAi (VSRs), thereby leading to question the physiological importance of the RNAi pathway in mammals. Here, we identified that wild-type Semliki Forest virus (SFV), a prototypic alphavirus, triggered the Dicer-dependent production of abundant viral (v)siRNAs in different mammalian somatic cells in the presence of VSR. These vsiRNAs were produced from viral dsRNA replicative intermediates, almost exclusively located at the 5’ termini of the viral genome, and loaded into AGO, and they were fully active in slicing cognate viral RNAs. Besides, Sindbis virus, another alphavirus, also induced vsiRNA generation in mammalian somatic cells. AGO2 deficiency increased SFV and SINV replication, while enoxacin, a known RNAi enhancer that functions at post steps of siRNA production, efficiently reduced viral replication. The nucleotide sequence at the 5’ termini of SFV and SINV genome is conserved among the Old World alphaviruses, and mutating the conserved sequences resulted in the recombinant SFV being deficient in vsiRNA production and irresponsive to antiviral RNAi. SFV infection also enabled the production of abundant vsiRNAs and antiviral RNAi in IFN-competent adult mice, and importantly, enhanced RNAi by enoxacin protected adult mice from lethal SFV challenge and reduced the virus-induced neuropathogenesis in the central neuron system. Overall, our findings provide evidence that mammalian antiviral RNAi is active in differentiated cells and adult mice with intact IFN response even in the presence of VSR and present a therapeutic strategy against alphaviruses that include many important emerging and reemerging human pathogens.

Project description:Alphavirus infection triggers antiviral RNAi immunity in mammals

Project description:Argonaute (AGO) proteins bind small RNAs to silence complementary RNA transcripts and are central to RNA interference (RNAi). AGO-crosslinking immunoprecipitation (AGO-CLIP) has illuminated RNAi networks, but bioinformatic analysis is laborious and lack of experimental tools hinders its application outside of model organisms. RNAi is critical for regulation of gene expression and defense against viral infection in the Aedes aegypti mosquito, which transmits Zika, chikungunya, dengue, and yellow fever viruses to cause human disease. We developed AGO-CLIP for both mosquito AGO proteins and a universal, streamlined software package for CLIP analysis, identifying 230 novel small RNAs and 5,447 small RNA targets that comprise a comprehensive RNAi network map. We used this unique resource to predict repression of small RNA targets in specific mosquito tissues. Notably, this resource revealed unexpected AGO target preferences and uncovered a new mode of AGO-mediated repression, findings that have broad implications for the study of antiviral RNAi.

Project description:Understanding the role of microRNAs in the interaction of Aedes aegypti mosquitoes with an insect-specific flavivirus

Project description:Aedes aegypti Piwi4 is a non-canonical PIWI protein involved in antiviral responses

Project description:Tissue specific role of the siRNA pathway against Dengue virus in Aedes aegypti mosquitoes

Project description:Aedes aegypti mosquitoes infect hundreds of millions of people each year with dangerous viral pathogens including dengue, yellow fever, Zika, and chikungunya. Progress in understanding the biology of this insect, and developing tools to fight it, depends on the availablity of a high-quality genome assembly. Here we use DNA proximity ligaton (Hi-C) and Pacific Biosciences long reads to create AaegL5 - a highly contiguous A. aegypti reference.

Project description:Most alphaviruses are transmitted by mosquito vectors and infect a wide range of vertebrate hosts, with a few exceptions. Eilat virus (EILV) in this genus is characterized by a host range restricted to mosquitoes. Its chimeric viruses have been developed as safe and effective vaccine candidates and diagnostic tools. Here, we investigated the interactions between these insect-specific viruses (ISVs) and mosquito cells, unveiling their potential roles in determining vector competence and arbovirus transmission. By RNA sequencing, we found that these ISVs profoundly modified host cell gene expression profiles. Two EILV-based chimeras, consisting of EILV’s nonstructural genes and the structural genes of Chikungunya virus (CHIKV) or Venezuelan equine encephalitis virus (VEEV), namely EILV/CHIKV (E/C) and EILV/VEEV (E/V), induced more intensive transcriptome regulation than parental EILV and activated different antiviral mechanisms in host cells. We demonstrated that E/C robustly promoted antimicrobial peptide production and E/V strongly upregulated the RNA interference pathway components. This also highlighted the intrinsic divergences between CHIKV and VEEV, representatives of the Old World and New World alphaviruses. In contrast, EILV triggered a limited antiviral response. We further showed that initial chimera infections efficiently inhibited subsequent pathogenic alphavirus replication, especially in the case of E/V infection, which almost prevented VEEV and Sindbis virus (SINV) superinfections. Altogether our study provided valuable information on developing ISVs as biological control agents.

Project description:The ability of many viruses to manipulate the host antiviral immune response often results in complex host-pathogen interactions. In order to study the interaction of dengue virus (DENV) with the Aedes aegypti immune response, we have characterized the DENV infection-responsive transcriptome of the immune-competent A. aegypti cell line Aag2. As in mosquitoes, DENV infection transcriptionally activated the cell line Toll pathway and a variety of cellular physiological systems. Most notably, however, DENV infection down-regulated the expression levels of numerous immune signaling molecules and antimicrobial peptides (AMPs). Functional assays showed that transcriptional induction of AMPs from the Toll and IMD pathways in response to bacterial challenge is impaired in DENV-infected cells. In addition, Escherichia coli, a gram-negative bacteria species, grew better when co-cultured with DENV-infected cells than with uninfected cells, suggesting a decreased production of AMPs from the IMD pathway in virus-infected cells. Pre-stimulation of the cell line with gram-positive bacteria prior to DENV infection had no effect on DENV titers, while pre-stimulation with gram-negative bacteria resulted in an increase in DENV titers. These results indicate that DENV is capable of actively suppressing immune responses in the cells it infects, a phenomenon that may have important consequences for virus transmission and insect physiology.

Project description:The ability of many viruses to manipulate the host antiviral immune response often results in complex host-pathogen interactions. In order to study the interaction of dengue virus (DENV) with the Aedes aegypti immune response, we have characterized the DENV infection-responsive transcriptome of the immune-competent A. aegypti cell line Aag2. As in mosquitoes, DENV infection transcriptionally activated the cell line Toll pathway and a variety of cellular physiological systems. Most notably, however, DENV infection down-regulated the expression levels of numerous immune signaling molecules and antimicrobial peptides (AMPs). Functional assays showed that transcriptional induction of AMPs from the Toll and IMD pathways in response to bacterial challenge is impaired in DENV-infected cells. In addition, Escherichia coli, a gram-negative bacteria species, grew better when co-cultured with DENV-infected cells than with uninfected cells, suggesting a decreased production of AMPs from the IMD pathway in virus-infected cells. Pre-stimulation of the cell line with gram-positive bacteria prior to DENV infection had no effect on DENV titers, while pre-stimulation with gram-negative bacteria resulted in an increase in DENV titers. These results indicate that DENV is capable of actively suppressing immune responses in the cells it infects, a phenomenon that may have important consequences for virus transmission and insect physiology. Infected (dengue virus or heat-inactivated dengue virus) vs. naive cells. 3 replicates each.